Receiving device and x-ray imaging apparatus having the same

ABSTRACT

There are provided a receiving device in which detectors of different sizes can be stably accommodated and an X-ray imaging apparatus having the same. A receiving device having a receiving unit in which a first detecting device is accommodated, the receiving device including a fixer provided in the receiving unit and into which a part of a surface of the first detecting device is inserted in order to prevent movement of the first detecting device, and a guide disposed at an inner side surface of the receiving unit and including a detector support having a side that is connected to a rotating shaft to be rotatable and configured to support at least one surface of the first detecting device and at least one surface of a second detecting device having a different size from the first detecting device.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation-In-Part of application Ser. No.14/861,436, filed Sep. 22, 2015, which claims priority from KoreanPatent Application No. 10-2014-0127201, filed on Sep. 23, 2014 in theKorean Intellectual Property Office, the disclosure of which isincorporated herein by reference.

BACKGROUND 1. Field

Embodiments of the present invention relate to a receiving device inwhich a detector is accommodated and an X-ray imaging apparatus havingthe same.

2. Description of the Related Art

An X-ray imaging apparatus is a non-invasive diagnostic apparatus thatradiates X-rays to a subject, detects X-rays transmitted through thesubject, and can image an internal structure of the subject.

Since general X-ray imaging apparatuses have an X-ray source and anX-ray detector, which are fixed in a certain space, a patient moves to alaboratory in which the X-ray imaging apparatus is positioned and moveshis or her body to adjust to the apparatus in order to perform X-rayimaging.

However, since movement-impaired patients have difficulty in imagingusing general X-ray imaging apparatuses, a mobile X-ray imagingapparatus capable of performing X-ray imaging at any place wasdeveloped.

The mobile X-ray imaging apparatus can perform X-ray imaging by directlyvisiting movement-impaired patients since an X-ray source is mounted ina movable main body and a portable X-ray detector is used.

The mobile X-ray imaging apparatus includes a receiving unit, and theportable X-ray detector may be accommodated in the receiving unit. Forconvenience of X-ray imaging, portable X-ray detectors of various sizeshave been recently provided.

When a portable X-ray detector of a small size is accommodated in areceiving container that is provided according to a size of a portableX-ray detector of a large size, the portable X-ray detector may move inthe receiving container when the mobile X-ray imaging apparatus ismoved. Therefore, the portable X-ray detector comes in contact with aninner sidewall of the receiving container so that noise may be generatedor the portable X-ray detector may be damaged.

In order to prevent the portable X-ray detector from being unstablyaccommodated in the receiving unit, the receiving unit of the mobileX-ray imaging apparatus may include the receiving container in whichreceiving units according to sizes of portable X-ray detectors havingvarious sizes are provided to accommodate portable X-ray detectors ofvarious sizes. In this case, since a size of the receiving unit in whichthe portable X-ray detector is accommodated increases, space utilizationis limited.

SUMMARY

According to an embodiment of the present invention, a receiving devicein which detecting devices of various sizes can be stably accommodatedin a receiving unit and an X-ray imaging apparatus having the same maybe provided.

According to an aspect of the present invention, there is provided areceiving device having a receiving unit in which a first detectingdevice is accommodated, the receiving device including: a fixer providedin the receiving unit and into which a part of a side surface of thefirst detecting device is inserted in order to prevent the firstdetecting device from being moved; and a detector support having a sidethat is connected to a rotating shaft and tiltable and configured tosupport at least one side surface of a second detecting device having asmaller size than the first detecting device.

An elastic member may be provided between the detector support and aninner side surface of the receiving unit, and the elastic member mayprovide an elastic force of pushing the detector support from the innerside surface of the receiving unit.

When the first detecting device is inserted into the receiving unit, thedetector support may be pressed by the first detecting device and tiltedto the inner side surface of the receiving unit.

A support bracket configured to support the elastic member may beprovided behind the detector support.

The detector support may be rotatably mounted in a side support that ismounted in an inner side surface of the receiving unit.

When the second detector is inserted into the receiving unit, at leastone side surface of the second detector may be supported by the sidesupport.

The detector support may have a tilting angle that is restricted by atilting restricting portion provided in the form of a groove or a holein a side surface.

The tilting restricting portion may be provided to be a part of aconcentric circle having the same center of rotation as a circle drawnby ends of the detector support.

The side support may include an intervention unit inserted into thetilting restricting portion.

The fixer may include a bottom fixer provided in a lower part of thereceiving unit and configured to support a bottom of the first detectingdevice or a bottom of the second detecting device.

When the first detecting device or the second detecting device ismounted in the bottom fixer, the first detecting device or the seconddetecting device may be charged.

The fixer may include a side fixer having an insertion groove into whichparts of both side surfaces of the first detecting device are inserted.

The side fixer may be provided in the left and right sides of thereceiving unit.

A rail may be provided in an inner side surface of the receiving unit,and the detector support may be movable along the rail.

A plurality of the detector supports may be provided.

According to another aspect of the present invention, there is providedan X-ray imaging apparatus, including: a movable main body; an X-raygenerator mounted in the main body and configured to generate X-rays; adetecting device configured to detect X-rays generated from the X-raygenerator; a receiving device mounted in the main body and having areceiving unit in which the detecting device is accommodated; and adetector support configured to support a side surface of a detectingdevice having a smaller horizontal length than the receiving unit.

The detector support may be tiltable with respect to a rotation axis.

An elastic member may be provided between the detector support and aninner side surface of the receiving unit.

The elastic member may have a directional elastic force that increases adistance between the detector support and the inner side surface of thereceiving unit.

When a detecting device having a horizontal length corresponding to ahorizontal length of the receiving unit is inserted into the receivingunit, the detector support may be pressed by the detecting device, and adistance between the detector support and an inner side surface of thereceiving unit may decrease.

The detector support may be tiltably mounted in a body in which areceiving unit in which the detector support is able to be accommodatedis formed.

The receiving unit may have left and right inner sides having a sidefixer into which a part of at least one side surface of the detectingdevice is inserted and fixed.

The receiving unit may have a lower part including a bottom fixer inwhich a mounting groove in which the detecting device is mounted andfixed is formed.

When the detecting device is mounted in the bottom fixer, the detectingdevice may be charged.

The receiving device may include a rail that horizontally extends, andthe detector support may be movable along the rail.

The rail may further include a stopper configured to restrict movementof the detector support.

A plurality of the detector supports may be provided.

The plurality of detector supports may be movable along a rail providedin the receiving device.

BRIEF DESCRIPTION OF THE DRAWINGS

These and/or other aspects of the invention will become apparent andmore readily appreciated from the following description of theembodiments, taken in conjunction with the accompanying drawings ofwhich:

FIG. 1 is a diagram illustrating a mobile X-ray imaging apparatusaccording to an embodiment of the present invention;

FIG. 2 is a perspective view of a receiving device according to anembodiment of the present invention;

FIG. 3 is a diagram illustrating a configuration of a receiving deviceaccording to an embodiment of the present invention;

FIG. 4 is a diagram illustrating a state in which a guide is mounted ina receiving device according to an embodiment of the present invention;

FIG. 5 is an exploded perspective view of a guide according to anembodiment of the present invention;

FIG. 6 is a diagram illustrating a guide according to an embodiment ofthe present invention;

FIG. 7 is a side view of a guide when the guide according to anembodiment of the present invention is in a first position;

FIG. 8 is a side view of a receiving device when a guide according to anembodiment of the present invention is in a first position;

FIG. 9 is a side view of a guide when the guide according to anembodiment of the present invention is in a second position;

FIG. 10 is a side view of a receiving device when the guide according toan embodiment of the present invention is in a second position;

FIG. 11 is an exploded perspective view of a guide according to anotherembodiment of the present invention;

FIG. 12 is a diagram illustrating a guide according to anotherembodiment of the present invention;

FIG. 13 is a side view of a guide when the guide according to anotherembodiment of the present invention is in a first position;

FIG. 14 is a side view of a receiving device when a guide according toanother embodiment of the present invention is in a first position;

FIG. 15 is a side view of a guide when the guide according to anotherembodiment of the present invention is in a second position;

FIG. 16 is a side view of a receiving device when a guide according toanother embodiment of the present invention is in a second position;

FIG. 17 is a diagram illustrating a part of a receiving device accordingto still another embodiment of the present invention; and

FIG. 18 is a diagram illustrating a part of a receiving device accordingto still another embodiment of the present invention.

DETAILED DESCRIPTION

Hereinafter, a receiving device according to an embodiment of thepresent invention and an X-ray imaging apparatus having the same will bedescribed in detail with reference to the drawings.

FIG. 1 is a diagram illustrating a mobile X-ray imaging apparatusaccording to an embodiment of the present invention.

As illustrated in FIG. 1, a mobile X-ray imaging apparatus 1 accordingto the embodiment of the present invention may include an X-raygenerator 2 and a detecting device 3. The X-ray generator 2 may bemounted in a main body 4, and the detecting device 3 may be accommodatedin a receiving device 10 provided in the main body 4. The main body 4 ismovable by a caster 6. The main body 4 includes a handgrip 41. A usermay move the main body 4 by grasping and pushing or pulling the handgrip41.

The X-ray generator 2 may receive a driving force from a driving unit(not illustrated) provided in the main body 4 and generate X-rays. X-rayenergy may be controlled by a tube voltage. An intensity or a dose ofX-rays may be controlled by a tube current and an X-ray exposure time.

The X-ray generator 2 is movable together with the main body 4. The mainbody 4 may include a moving unit 5. The moving unit 5 may include afirst guide rail 51 and a second guide rail 52. The first guide rail 51and the second guide rail 52 may be installed to form a predeterminedangle.

As an example, the first guide rail 51 may be perpendicular to thesecond guide rail 52. The first guide rail 51 may vertically extend froma bottom surface on which the main body 4 is mounted. The second guiderail 52 may horizontally extend from the bottom surface on which themain body 4 is mounted. The second guide rail 52 is movable along thefirst guide rail 51. The first guide rail 51 may extend in a y axisdirection, the second guide rail 52 may extend in an x axis direction,and the second guide rail 52 is movable in a vertical direction(direction A) along the y axis.

The X-ray generator 2 may be mounted in the second guide rail 52. TheX-ray generator 2 is movable in a direction in which the second guiderail 52 extends. That is, the X-ray generator 2 is movable in adirection (direction B) that is horizontal to the bottom surface alongthe x axis.

Also, the X-ray generator 2 is rotatable about the x axis or a z axis.The X-ray generator 2 is connected to the second guide rail 52 by arotary joint 53 that is rotatable, and may rotate (direction C) aboutthe x axis or rotate (direction D) about the z axis by a connecting unit53.

A position and an angle of rotation of the X-ray generator 2 may beregulated by the moving unit 5 and the rotary joint 53 according to aposition of a subject to be imaged using X-rays.

The main body 4 may include a driving unit configured to regulate theposition and angle of rotation of the X-ray generator 2. The drivingunit may be a motor that is electrically driven.

A manipulating unit configured to input various pieces of informationabout X-ray imaging and manipulate respective devices may be provided ata side of the main body 4. The manipulating unit may receive a commandfrom a user and transmit the command to a control unit, which will bedescribed below.

The control unit (not illustrated) may be provided inside the main body4. The control unit may control the X-ray generator 2 to control x-raygeneration. Also, the control unit may receive an electrical signal fromthe detecting device 3 and generate an X-ray image.

A mobile detecting device 3 may be provided. The detecting device 3 maybe accommodated in a receiving unit 11 of the receiving device 10 thatis provided in the main body 4. The detecting device 3 may be moved to aposition at which X-ray imaging is required along with the main body 4.When X-ray imaging is required, the user may withdraw the detectingdevice 3 from the receiving device 10, enable the detecting device 3 tobe positioned behind the subject to be imaged using X-rays, and performX-ray imaging.

The detecting device 3 may include a detector and a grid. The detectormay detect X-rays that pass through the subject and convert the X-raysinto an electrical signal. X-ray data of the subject may be obtained bythe detector. The grid may be positioned in front of the detector toblock scattered rays of X-rays generated from the X-ray generator 2.

The detecting device 3 may be fixed not to move in the receiving unit 11provided in the receiving device 10. The receiving unit 11 may beprovided according to a size of the detecting device 3 and fix at leastone side of the detecting device 3. Therefore, it is possible to preventthe detecting device 3 from moving in the receiving unit 11, collidingwith an inner side surface of the receiving device 10 forming thereceiving unit 11, and generating noise, or prevent the detecting device3 from being damaged.

The detecting device 3 may have a substantially rectangular shape. Ashape of the detecting device 3 is not limited to the rectangular shape.However, the detecting device 3 will be described below as having arectangular shape.

When X-ray imaging is performed, the detecting device 3 of a differentsize may be used as necessary. For example, the detecting device 3 of alarge or small size may be used according to an area of the subject tobe imaged using X-rays. The detecting device 3 having a square shape maybe used, or the detecting device 3 having a rectangular shape whosehorizontal length is greater than a vertical length may be used.

If the receiving unit 11 provided in the receiving device 10 is providedaccording to a size of the biggest detecting device 3, when a detectingdevice having a smaller size than the biggest detecting device 3 isinserted into the receiving unit, the detecting device may collide withan inner side surface of the receiving device forming the receiving unitaccording to movement of the main body 4, and the detecting device maybe damaged, or clattering noise may be generated.

In order to accommodate and fix the detecting devices 3 of differentsizes not to move, a structure in which receiving units of various sizesare provided in the receiving device to correspond to various sizes ofdetecting devices may be considered. In this case, since a plurality ofreceiving units of different sizes need to be provided in the receivingdevice, space utilization may be limited.

Hereinafter, the receiving device 10 in which detecting devices ofdifferent sizes can be stably accommodated without constraints on spaceutilization of the receiving device 10 will be described.

FIG. 2 is a perspective view of a receiving device according to anembodiment of the present invention. FIG. 3 is a diagram illustrating aconfiguration of a receiving device according to an embodiment of thepresent invention. FIG. 4 is a diagram illustrating a state in which aguide is mounted in a receiving device according to an embodiment of thepresent invention.

As illustrated in FIGS. 2 to 4, the receiving device 10 according to theembodiment of the present invention may include the receiving unit 11 inwhich the detecting device 3 can be accommodated. The receiving unit 11may be formed to correspond to the size of the biggest detecting deviceamong detecting devices of various sizes that can be used when X-rayimaging is performed.

A flange portion 15 may be formed at a side of the receiving device 10.The receiving device 10 may be combined with the main body 4 by theflange portion 15 and a fastening member penetrating through a side ofthe main body 4. A method in which the receiving device 10 is mounted inthe main body 4 is not limited to the above. The receiving device 10 maybe fixed to the main body 4, and detachable from the main body 4.

Fixers 12 and 13 into which a part of the detecting device 3 can beinserted and fixed may be provided in the receiving unit 11. The fixers12 and 13 may include the side fixer 12 into which parts of the left andright sides of the detecting device 3 can be inserted and fixed and thebottom fixer 13 configured to support a bottom surface of the detectingdevice 3.

The side fixer 12 may include a first side fixer 12 a and a second sidefixer 12 b which are provided in the left and right sides of thereceiving unit 11, respectively. A first insertion groove 120 a and asecond insertion groove 120 b into which parts of the left and rightsides of the detecting device 3 can be inserted may be provided in thefirst side fixer 12 a and the second side fixer 12 b. Widths D1 of thefirst insertion groove 120 a and the second insertion groove 120 b maycorrespond to a width d1 of a side surface of the detecting device 3.

A part of a side surface of the detecting device 3 may be inserted intoand fixed to the first insertion groove 120 a and the second insertiongroove 120 b. The first insertion groove 120 a and the second insertiongroove 120 b may extend in a vertical direction such that the part ofthe side surface of the detecting device 3 may be slidably inserted.

A length L1 from one surface 121 a of the first insertion groove 120 ato one surface 121 b of the second insertion groove 120 b may correspondto a horizontal length of a detecting device having the greatesthorizontal length among detecting devices of various sizes that can beused when X-ray imaging is performed. The detecting device having thegreatest horizontal length may slide in a longitudinal direction of thefirst insertion groove 120 a and the second insertion groove 120 b whena part of a left side of the detecting device 3 is inserted into thefirst insertion groove 120 a and a part of a right side of the detectingdevice 3 is inserted into the second insertion groove 120 b. Therefore,the detecting device may be accommodated in the receiving unit 11,inserted into the first insertion groove 120 a and the second insertiongroove 120 b, and the left and right sides may be fixed not to move.

The bottom fixer 13 may include a mounting portion 130 on which a bottomof the detecting device 3 may be mounted. A part of the bottom of thedetecting device 3 may be inserted into the mounting portion 130. A partof the bottom of the detecting device 3 may be inserted into themounting portion 130 and fixed not to move. A width D2 of the mountingportion 130 may correspond to a width d2 of the bottom of the detectingdevice 3.

The bottom fixer 13 may be formed of a material capable of absorbing animpact to prevent an impact that may be applied to the detecting device3 in a process in which the detecting device 3 is accommodated in thereceiving unit 11 of the receiving device 10. As an example, the bottomfixer 13 may be formed of an elastic material. Preferably, at least apart of the bottom fixer 13 coming in contact with the detecting device3 may be formed of an elastic material. In other words, at least a partof the mounting portion 130 of the bottom fixer 13 may be formed of anelastic material. As an example, the elastic material may includerubber, silicone, and the like.

A connector 300 capable of charging the detecting device 3 may beprovided in the receiving unit 11 of the receiving device 10.Specifically, the connector 300 may be provided at the bottom fixer 13.More specifically, the connector 300 may be provided at the mountingportion 130 on which the bottom of the detecting device 3 is mounted.When the detecting device 3 is accommodated in the receiving unit 11 ofthe receiving device 10, a terminal 310 (see FIG. 8) provided in thedetecting device 3 and the connector 300 provided in the receivingdevice 10 may come in contact with each other. By such a structure, thedetecting device 3 may be charged while being accommodated in thereceiving unit 11 of the receiving device 10. As an example, theterminal 310 provided in the detecting device 3 and the connector 300provided in the receiving device 10 may be docked by a magnetic force.Also, the detecting device 3 may transmit and receive an electricalsignal to and from the control unit (not illustrated) by being docked tothe connector 300 provided in the receiving device 10.

A support 14 capable of supporting a rear surface of the detectingdevice 3 may be provided in the inner side surface of the receivingdevice 10 forming the receiving unit 11. The support 14 may be providedin at least one of an inner front surface 110 and an inner rear surface111 of the receiving device 10 forming the receiving unit 11.

A length D3 by which the support 14 protrudes forward may correspond toa length D4 from the inner rear surface 111 of the receiving device 10to the first insertion groove 120 a and the second insertion groove 120b of the side fixers 12 a and 12 b provided at each side of thereceiving unit 11. When the left and right sides of the detecting device3 are inserted into the first insertion groove 120 a and the secondinsertion groove 120 b, the rear surface of the detecting device 3 maybe supported by the support 14. Therefore, the detecting device 3 may bestably accommodated in the receiving unit 11.

A guide 20 may be provided in the inner side surface of the receivingdevice 10 forming the receiving unit 11. The guide 20 may be provided inat least one of the inner front surface 110 and the inner rear surface111 of the receiving device 10 forming the receiving unit 11.Hereinafter, a case in which the guide 20 is provided in the inner frontsurface 110 of the receiving device 10 will be described.

The guide 20 includes a first side portion 21 and a second side portion22 which are disposed to face each other with a predetermined intervaltherebetween. A detector support 23 configured to rotate a predeterminedangle with respect to a rotation axis may be provided between the firstside portion 21 and the second side portion 22.

The guide 20 may support a front surface of the detecting device 3 or aside surface of the detecting device 3. When a horizontal length L ofthe detecting device 3 is the same as a length L1 from the one surface121 a of the first insertion groove 120 a formed in the first side fixer12 a to the one surface 121 b of the second side fixer 12 b, the guide20 may support the front surface of the detecting device 3.

When a length from the one surface 121 a of the first insertion groove120 a to the first side portion 21 of the guide 20 is set to L2, and alength from the second side portion 22 of the guide 20 to the onesurface 121 b of the second insertion groove 120 b is set to L3, aone-side surface of the detecting device 3 whose horizontal length is L2comes in contact with the one surface 121 a of the first insertiongroove 120 a, and the other-side surface may be inserted into thereceiving unit 11 to come in contact with the first side portion 21 ofthe guide 20. The detecting device 3 whose horizontal length is L2 maybe fixed not to move inside the receiving unit 11 when a right-sidesurface is inserted into and fixed to the first insertion groove 120 a,and a left-side surface is supported by the first side portion 21 of theguide 20.

Also, the detecting device 3 whose horizontal length is L3 may beinserted into the receiving unit 11 such that a one-side surface thereofcomes in contact with the one surface 121 b of the second insertiongroove 120 b, and the other-side surface thereof comes in contact withthe second side portion 22 of the guide 20. The detecting device 3 whosehorizontal length is L3 may be fixed not to move inside the receivingunit 11 when a right-side surface is supported by the second sideportion 22 of the guide 20 and a left-side surface is inserted into andfixed to the second insertion groove 120 b.

Hereinafter, a detailed configuration of the guide 20 will be describedin detail with reference to the drawings.

FIG. 5 is an exploded perspective view of a guide according to anembodiment of the present invention. FIG. 6 is a diagram illustrating aguide according to an embodiment of the present invention.

As illustrated in FIGS. 5 and 6, the guide 20 according to theembodiment of the present invention includes the detector support 23that is pivotally mounted on the inner side surface of the receivingdevice 10. The detector support 23 may be mounted on the inner sidesurface of the receiving device 10 by the first side portion 21 and thesecond side portion 22. The first side portion 21 and the second sideportion 22 may be disposed to face each other with a predeterminedinterval therebetween and fixed to the inner side surface of thereceiving device 10.

The detector support 23 may be positioned between the first side portion21 and the second side portion 22. The detector support 23 may bepivotally mounted on the first side portion 21 and the second sideportion 22 by a rotating shaft 26. The rotating shaft 26 may passthrough a rotating shaft insertion hole 210 formed in the first sideportion 21, a rotating shaft insertion hole 230 formed at a side of thedetector support 23, and a rotating shaft insertion hole 220 formed inthe second side portion 22. The detector support 23 may be pivoted aboutthe rotating shaft 26.

An elastic member 24 may be provided between one surface of the detectorsupport 23 and the inner front surface 110 of the receiving device 10.The elastic member 24 may provide an elastic force such that thedetector support 23 faces the inner rear surface 111 of the receivingdevice 10. That is, the elastic member 24 may provide an elastic forceof pushing the detector support 23 from the inner front surface 110 tothe detector support 23. The elastic member 24 may be a spiral spring.

The receiving device 10 may include a support bracket 25 configured tosupport the elastic member 24. The support bracket 25 may be positionedbetween the detector support 23 and the inner front surface 110 of thereceiving device 10. The support bracket 25 may be mounted on at leastone of the first side portion 21 and the second side portion 22. Whenthe detector support 23 is pressed by the detecting device 3 that isinserted into the receiving unit 11, the elastic member 24 may becompressed between the detector support 23 and the support bracket 25.

The support bracket 25 may include an elastic member fixer 250. As anexample, the elastic member fixer 250 may protrude from one surface ofthe support bracket 25, and the elastic member 24 may be mounted in theelastic member fixer 250.

The detector support 23 may include an elastic member insertion groove232 into which the elastic member 24 can be inserted. The elastic member24 has a position that is fixed by the elastic member fixer 250 of thesupport bracket 25, is inserted into the elastic member insertion groove232, and can press the other side of the detector support 23 backward.

A rotation restricting portion 231 may be provided in a side portion ofthe detector support 23. The rotation restricting portion 231 may beprovided in the form of a groove or a hole having a predeterminedlength. An intervention unit 211 that can be inserted into the rotationrestricting portion 231 may be provided in any of the first side portion21 and the second side portion 22. FIG. 5 illustrates an embodiment inwhich an intervention hole 211 a into which the intervention unit 211can be inserted is formed in the first side portion 21, and theintervention unit 211 is inserted into and fixed to the interventionhole 211 a. A configuration of the intervention unit 211 is not limitedto the above. The intervention unit 211 may protrude from the first sideportion 21 together with the first side portion 21.

The intervention unit 211 is inserted into the rotation restrictingportion 231, and may restrict an angle at which the detector support 23rotates forward or backward. In this case, the rotation restrictingportion 231 may be formed to be a part of a concentric circle having thesame center of rotation as a circle drawn by ends of the detectorsupport 23 when the detector support 23 rotates about the rotating shaft26.

Hereinafter, an operation of the guide 20 when the detecting device 3 ofa different size is inserted into the receiving unit 11 will bedescribed.

FIG. 7 is a side view of a guide when the guide according to anembodiment of the present invention is in a first position. FIG. 8 is aside view of a receiving device when a guide according to an embodimentof the present invention is in a first position.

As illustrated in FIGS. 7 and 8, when the detecting device 3 is insertedinto the receiving device 10 according to the embodiment of the presentinvention, the detector support 23 may be rotated forward (direction t1:refer to FIG. 7) by the detecting device 3. In this case, a length L bywhich the detecting device 3 horizontally extends may correspond to alength L1 from the one surface 121 a of the first insertion groove 120 ato the one surface 121 b of the second insertion groove 120 b of theside fixer 12 provided in the receiving device 10.

In the detecting device 3, a part of a side surface of the detectingdevice 3 may be slidably inserted into the first insertion groove 120 aand the second insertion groove 120 b formed in the first side guide 12a and the second side guide 12 b. In the detector support 23, one sideis rotatable by the rotating shaft 26 and the other side may face behindthe receiving device 10 due to an elastic force of the elastic member24. The other side of the detector support 23 may be rotated at apredetermined angle by the rotation restricting portion 231 and theintervention unit 211 and then stopped. The other side of the detectorsupport 23 may come in contact with the inner rear surface 111 of thereceiving device 10 forming the receiving unit 11.

The detecting device 3 may slide along the first insertion groove 120 aand the second insertion groove 120 b formed in the first side guide 12a and the second side guide 12 b, and may push and slide the detectorsupport 23 when the detecting device 3 comes in contact with one surface23 a of the detector support 23. The detector support 23 may be rotatedin the direction t1 with respect to the rotating shaft 26, and the otherside of the detector support 23 may face the front surface 110 of thereceiving device 10. When the detector support 23 is rotated in thedirection t1, the elastic member 24 may be compressed between thedetector support 23 and the front surface 110 of the receiving device10. The elastic member 24 can press the support bracket 25. The otherside of the detector support 23 may support one surface of the detectingdevice 3 such that the detecting device 3 can be stably accommodated inthe receiving unit 11.

In this manner, when the detecting device 3 having a horizontallyextending length L that corresponds to a length L1 from the one surface121 a of the first insertion groove 120 a to the one surface 121 b ofthe second insertion groove 120 b of the side fixer 12 provided in thereceiving device 10 is inserted into the receiving unit 11, the detectorsupport 23 may be rotated by the detecting device 3 not to interferewith movement of the detecting device 3.

The detecting device 3 may be accommodated in the receiving unit 11 whena front surface comes in contact with the detector support 23, a rearsurface comes in contact with the support 14, and parts of both sidesurfaces are inserted into the first insertion groove 120 a and thesecond insertion groove 120 b.

The receiving unit 11 of the receiving device 10 may be formed at aslant to have a predetermined angle. In other words, the receiving unit11 of the receiving device 10 may be formed to be inclined to have apredetermined angle with respect to a virtual line G extending in thedirection of gravity. Preferably, the receiving unit 11 of the receivingdevice 10 may be formed to be inclined to have an angle greater than 0°and equal to or less than 90° with respect to the virtual line Gextending in the direction of gravity. More preferably, the receivingunit 11 of the receiving device 10 may be formed to be inclined to havean angle greater than 0° and equal to or less than 45° with respect tothe virtual line G extending in the direction of gravity. As an example,FIG. 8 illustrates the receiving unit 11 of the receiving device 10formed to be inclined to have an angle of about 26° with respect to thevirtual line G extending in the direction of gravity. When the receivingunit 11 of the receiving device 10 is formed in parallel to the virtualline G extending in the direction of gravity, because the size ofgravity acting on the detecting device 3 is relatively large, arelatively large impact may be applied to the detecting device 3 whenthe detecting device 3 is accommodated in the receiving unit 11 of thereceiving device 10. Conversely, when the receiving unit 11 of thereceiving device 10 is formed to be inclined to have an angle of 90°with respect to the virtual line G extending in the direction ofgravity, because the size of gravity acting on the detecting device 3 isrelatively small, a relatively small impact may be applied to thedetecting device 3 when the detecting device 3 is accommodated in thereceiving unit 11 of the receiving device 10. However, when thereceiving unit 11 of the receiving device 10 is formed to be inclined tohave an angle of 90° with respect to the virtual line G extending in thedirection of gravity, a user has to accept inconvenience of having tobend his or her waist and the like to store the detecting device 3 inthe receiving unit 11 of the receiving device 10. Consequently, it ispreferable that the receiving unit 11 of the receiving device 10 beformed to be inclined to have an angle greater than 0° and less than 90°with respect to the virtual line G extending in the direction ofgravity. However, because an amount of impact applied to the detectingdevice 3 may be defined by various parameters such as a weight of thedetecting device 3 and a frictional coefficient of the detecting device3, the extent to which the receiving unit 11 of the receiving device 10is inclined is not limited to the above example. For reference, an angleof the receiving unit 11 of the receiving device 10 is measured withrespect to a surface of the detecting device 3 accommodated in thereceiving unit 11 of the receiving device 10. As an example, in the caseof FIG. 8, the angle of the receiving unit 11 of the receiving device 10is measured with respect to a surface of the detecting device 3 facingthe inner rear surface 111.

Hereinafter, a case in which the detecting device 3 whose horizontallyextending length is L that is the same as a length L2 from the onesurface 121 a of the first insertion groove 120 a to the first sideportion 21 of the guide 20 is stably accommodated in the receiving unit11 of the receiving device 10 will be described.

FIG. 9 is a side view of a guide when a guide according to an embodimentof the present invention is in a second position. FIG. 10 is a side viewof a receiving device when a guide according to an embodiment of thepresent invention is in a second position.

As illustrated in FIGS. 9 and 10, a horizontally extending length L ofthe detecting device 3 according to the embodiment of the presentinvention may be any of a length L2 from the one surface 121 a of thefirst insertion groove 120 a of the side fixer 12 to the first sideportion 21 of the guide 20 and a length L3 from the one surface 121 b ofthe second insertion groove 120 b of the side fixer 12 to the secondside portion 22 of the guide 20. Hereinafter, the horizontally extendinglength L of the detecting device 3 will be described as the length L2from the one surface 121 a of the first insertion groove 120 a of theside fixer 12 to the first side portion 21 of the guide 20.

Meanwhile, when the detecting device 3 whose horizontally extendinglength L corresponds to the length L1 from the one surface 121 a of thefirst insertion groove 120 a to the one surface 121 b of the secondinsertion groove 120 b of the side fixer 12 provided in the receivingdevice 10 is removed from the receiving unit 11, a force pressing thedetector support 23 is removed, and the other side of the detectorsupport 23 may be rotated to face behind the accommodating member 10 dueto the elastic force of the elastic member 24. That is, the detectorsupport 23 may rotate in a direction t3 that is a direction opposite tothe direction t1 with respect to the rotating shaft 26.

The detector support 23 has a rotating angle that may be restricted bythe intervention unit 211 inserted into the rotation restricting portion231. The detector support 23 may be rotated at a maximum rotating angleby the rotation restricting portion 231 and the intervention unit 211and then stopped. Meanwhile, the detector support 23 may be rotateduntil the other side thereof comes in contact with an inner rear surfaceof the receiving device 10 forming the receiving unit 11.

When the detector support 23 is rotated in the direction t3, the elasticmember 24 positioned between the detector support 23 and the supportbracket 25 can expand. At least a part of the elastic force stored inthe contracted elastic member 24 is used to rotate the detector support23. When the detector support 23 is rotated at a predetermined angle,the elastic member 24 may expand and have an elastic force smaller thanthat before the detector support 23 is rotated.

When the detecting device 3 whose horizontally extending length is L1 isremoved from the receiving unit 11, a first section (length: L1) fromthe one surface 121 a of the first insertion groove 120 a of the sidefixer 12 to one surface of the second insertion groove 120 b may bepartitioned by the detector support 23 into a second section (length:L2) from the one surface 121 a of the first insertion groove 120 a tothe first side portion 21 of the guide 20 and a third section (length:L3) from the second side portion 22 to the one surface 121 b of thesecond insertion groove 120 b.

A detecting device 3 a whose horizontally extending length is L2 may beinserted into the second section in the receiving unit 11. A detectingdevice whose horizontally extending length is L3 may be inserted intothe third section in the receiving unit 11. When the detecting device 3a whose horizontally extending length is L2 is inserted into the secondsection in the receiving unit 11, the guide 20 remains in a state beforethe detecting device 3 a is inserted, a part of a one-side surface ofthe detecting device 3 a is inserted into and fixed to the firstinsertion groove 120 a, the other-side surface is supported by aone-side surface of the detector support 23, and thus the detectingdevice 3 a may be fixed not to move. A part of the bottom of thedetecting device 3 a may be inserted into and fixed to the mountingportion 130 provided in the bottom fixer 13.

The connector 300 capable of charging the detecting device 3 a may beprovided in the receiving unit 11 of the receiving device 10.Specifically, the connector 300 may be provided at the bottom fixer 13.More specifically, the connector 300 may be provided at the mountingportion 130 on which the bottom of the detecting device 3 a is mounted.When the detecting device 3 a is accommodated in the receiving unit 11of the receiving device 10, the terminal 310 (see FIG. 10) provided inthe detecting device 3 a and the connector 300 provided in the receivingdevice 10 may come in contact with each other. By such a structure, thedetecting device 3 a may be charged while being accommodated in thereceiving unit 11 of the receiving device 10. Additional description ofthe connector 300 will be omitted because the description overlaps thatwith reference to FIGS. 2 to 4.

The detecting device whose horizontally extending length is L3 may beinserted into the third section in the receiving unit 11. In this case,the guide 20 remains in a state that is the same before and after thedetecting device is inserted, a one-side surface of the detecting deviceis supported by the detector support, and the other-side surface of thedetecting device may be inserted into and fixed to the second insertiongroove 120 b. A part of the bottom of the detecting device can beinserted into and fixed to the mounting portion 130 provided in thebottom fixer 13.

In this manner, even when the detecting devices have various sizes, thedetecting devices may be stably accommodated in the receiving unit 11according to the structure of the guide 20. Therefore, it is possible toprevent the detecting device from being moved when the main body 4 ismoved.

FIG. 11 is an exploded perspective view of a guide according to anotherembodiment of the present invention. FIG. 12 is a diagram illustrating aguide according to another embodiment of the present invention.

In a receiving device 10′ according to another embodiment of the presentinvention illustrated in FIGS. 11 to 16, configurations other than adetailed configuration of a guide 50 may be similar to those of FIGS. 1to 10. Hereinafter, a detailed configuration of the guide 50 accordingto another embodiment of the present invention will be describedfocusing on differences from the guide 20 illustrated in FIGS. 1 to 10.

As illustrated in FIGS. 11 and 12, the guide 50 according to anotherembodiment of the present invention may include a body 51 and a detectorsupport 54. The detector support 54 may be mounted in the body 51 androtatable about a rotating shaft 55. The rotating shaft 55 may passthrough a side of the body 51 and the detector support 54, and thusenable the detector support 54 to be rotated and mounted in the body 51.

The body 51 may include a receiving unit 510 in which the detectorsupport 54 can be accommodated. The receiving unit 510 may be providedto correspond to a shape of the detector support 54. With respect to thereceiving unit 510, the body 51 positioned in one side of the detectorsupport 54 may be referred to as a first sidewall 51 a, and the body 51positioned in the other side may be referred to as a second sidewall 51b. A part of the body 51 facing one surface of the detector support 54may be referred to as a support surface 53.

An elastic member 56 may be positioned between the detector support 54and the support surface 53. The elastic member 56 may provide an elasticforce such that the other side of the detector support 54 is away fromthe support surface 53.

As an example, the elastic member 56 may be provided in the form of aspring whose two arms protrude from a circular spring portion. Any onearm may support one surface of the detector support 54, and the otherarm may support one surface of the detector support 54. The rotatingshaft 55 may be inserted into the circular spring portion connecting twoarms. A plurality of elastic members 56 may be provided. As an example,two elastic members 56 may be provided.

An elastic member receiving unit 541 in which the elastic member 56 canbe accommodated may be provided on the other surface of the detectorsupport 54. When the two elastic members 56 are provided, the elasticmember receiving unit 541 may include a first elastic member receivingunit 541 a in which any one elastic member is accommodated and a secondelastic member receiving unit 541 b in which the other elastic member isaccommodated.

A rotating shaft insertion hole 540 into which the rotating shaft 55 canbe inserted may be provided at a side of the detector support 54.Rotating shaft insertion holes 52 a and 52 b into which the rotatingshaft 55 can be inserted may be formed in the first side portion 51 aand the second side portion 51 b of the body 51. The rotating shaft 55may sequentially pass the rotating shaft insertion hole 52 b formed inthe second side portion 51 b of the body 51, the rotating shaftinsertion hole 540 formed in the detector support 54, and the rotatingshaft insertion hole 52 a formed in the first side portion 51 a.Therefore, the detector support 54 may be rotatably mounted in the body51.

When the elastic member 56 is mounted in the rotating shaft 55, therotating shaft 55 may sequentially pass the rotating shaft insertionhole 52 b formed in the second side portion 51 b of the body 51, therotating shaft insertion hole 540 formed in the detector support 54, aspring portion of the elastic member 56, and the rotating shaftinsertion hole 52 a formed in the first side portion 51 a.

As illustrated in FIG. 2 to FIG. 4, the guide 50 may be mounted in afront inner side surface of the receiving device 10 forming thereceiving unit 11. The guide 50 may be mounted in a rear inner sidesurface of the receiving device.

FIG. 13 is a side view of a guide when a guide according to anotherembodiment of the present invention is in a first position. FIG. 14 is aside view of a receiving device when a guide according to anotherembodiment of the present invention is in a first position.

As illustrated in FIGS. 13 and 14, when a detecting device 3′ isinserted into the receiving device 10′ in which the guide 50 accordingto another embodiment of the present invention is mounted, the otherside of the detector support 54 may be rotated to move forward(direction t5: refer to FIG. 13) by the detecting device 3′.

The detector support 54 may be rotated in the direction t5 andaccommodated in the receiving unit 510 positioned between the first sideportion 51 a and the second side portion 51 b. In this case, ahorizontally extending length of the detecting device 3′ may correspondto a length from one surface of a first insertion groove of the sidefixer 12 provided in the receiving device 10′ to one surface of a secondinsertion groove.

In this case, an arm supporting the detector support 54 between two armsof the elastic member 56 positioned between the detector support 54 andthe support surface 53 may move in a direction t6, and a distancebetween the two arms may decrease.

In the detecting device 3′, a part of a side surface of the detectingdevice 3′ may be slidably inserted into the first insertion groove andthe second insertion groove formed in the first side guide and thesecond side guide. The detector support 54 may slide along the firstinsertion groove and the second insertion groove, and may slidably pushthe detector support 54 when coming in contact with the detector support54. In the detector support 54, the other side of the detector support54 may be rotated in the direction t5 with respect to the rotating shaft55 due to a pushing force of the detecting device 3′ and accommodated inthe receiving unit 510 provided in the body 51.

In this manner, a part of a one-side surface of the detecting device 3′is inserted into the first insertion groove of the side fixer, a part ofthe other-side surface is inserted into the second insertion groove ofthe side fixer, and thus both sides may be fixed. Also, a bottom of thedetecting device 3′ may be mounted in and supported by the mountingportion 130 provided in the bottom fixer 13 that is positioned below areceiving unit 11′. Therefore, the detecting device 3′ may be stablyaccommodated in the receiving unit 11′ not to move even when the mainbody 4 is moved.

The connector 300 capable of charging the detecting device 3′ may beprovided in the receiving unit 11 of the receiving device 10.Specifically, the connector 300 may be provided at the bottom fixer 13.More specifically, the connector 300 may be provided at the mountingportion 130 on which the bottom of the detecting device 3′ is mounted.When the detecting device 3′ is accommodated in the receiving unit 11 ofthe receiving device 10, the terminal 310 provided in the detectingdevice 3′ and the connector 300 provided in the receiving device 10 maycome in contact with each other. By such a structure, the detectingdevice 3′ may be charged while being accommodated in the receiving unit11′ of the receiving device 10. Additional description of the connector300 will be omitted because the description overlaps that with referenceto FIGS. 2 to 4.

When the detector support 54 is inserted into the receiving unit 510 dueto an external force, the detecting device 3′ of a great horizontallyextending length may also be easily inserted into the receiving unit 11′without intervention of the detector support 54.

The receiving unit 11′ of the receiving device 10′ may be formed at aslant to have a predetermined angle. Description thereof will be omittedbecause the description overlaps that of the receiving unit 11 of thereceiving device 10.

Hereinafter, a case in which a detecting device of a short horizontallyextending length is inserted into the receiving unit 11′ will bedescribed.

FIG. 15 is a side view of a guide when the guide according to anotherembodiment of the present invention is in a second position. FIG. 16 isa side view of a receiving device when a guide according to anotherembodiment of the present invention is in a second position.

As illustrated in FIGS. 15 and 16, a detecting device 3 a′ according toanother embodiment of the present invention has a horizontally extendinglength that is any of a length from one surface of the first insertiongroove of the side fixer to the first side portion 51 a of the guide 50and a length from one surface of the second insertion groove to thesecond side portion 51 b of the guide 50. Hereinafter, the horizontallyextending length of the detecting device 3 a′ will be described as thelength from one surface of the first insertion groove of the side fixerto the first side portion 51 a of the guide 50.

When the detecting device 3 a′ illustrated in FIGS. 13 and 15 is removedfrom the receiving unit 11′, the detector support 54 may rotate in adirection t7 with respect to the rotating shaft 55 due to an elasticforce of the elastic member 56, and be removed from the receiving unit510 of the body 51. When the detector support 54 is rotated in thedirection t7, at least a part of the elastic force of the elastic member56 positioned between the detector support 54 and the support surface 53is used to rotate the detector support 54. When the detector support 54is rotated at a predetermined angle, the elastic member 56 may expandand have an elastic force smaller than that before the detector support54 is rotated. When the detector support 54 is rotated in the directiont7, an arm of the elastic member 56 supporting an inner side surface ofthe detector support 54 may move in a direction t8 while the inner sidesurface of the detector support 54 is supported. The direction t7 andthe direction t8 may be the same direction. Therefore, a distancebetween the arm supporting the inner side surface of the detectorsupport 54 and the arm supporting the support surface 53 of the body 51may increase.

As an example, when the detecting device 3 a′ whose horizontallyextending length is L1 is removed from the receiving unit 11′, a firstsection (length: L1) from one surface of the first insertion groove ofthe side fixer to one surface of the second insertion groove may bepartitioned by the detector support 54 into a second section (length:L2) from the one surface of the first insertion groove to the first sideportion 51 a of the guide 50 and a third section (length: L3) from thesecond side portion 51 b to the one surface of the second insertiongroove.

The detecting device 3 a′ whose horizontally extending length is L2 maybe inserted into the second section in the receiving unit 11′ and thedetecting device whose horizontally extending length is L3 may beinserted into the third section in the receiving unit 11′. When thedetecting device 3 a′ whose horizontally extending length is L2 isinserted into the second section in the receiving unit 11′, the guide 50remains in a state before the detecting device 3 a′ is inserted, a partof a one-side surface of the detecting device 3 a′ is inserted into andfixed to the first insertion groove, the other-side surface is supportedby a one-side surface of the detector support 54, and thus the detectingdevice 3 a′ may be fixed not to move. A part of a bottom of thedetecting device 3 a′ may be inserted into and fixed to a mountingportion provided in a bottom fixer 13′.

A detecting device whose horizontally extending length is L3 may beinserted into the third section in the receiving unit 11′. In this case,the guide 50 remains in a state that is the same before and after thedetecting device is inserted, a one-side surface of the detecting deviceis supported by the detector support, and the other-side surface of thedetecting device may be inserted into and fixed to the second insertiongroove. A part of the bottom of the detecting device may be insertedinto and fixed to the mounting portion provided in the bottom fixer 13′.

In this manner, when the detecting devices have various sizes, thedetecting devices can be stably accommodated by the receiving unit 11′according to the structure of the guide 50. Therefore, it is possible toprevent the detecting device from being moved when the main body 4 ismoved.

The receiving unit 11′ of the receiving device 10′ may be formed at aslant to have a predetermined angle. Description thereof will be omittedbecause the description overlaps that of the receiving unit 11 of thereceiving device 10.

FIG. 17 is a diagram illustrating a part of a receiving device accordingto still another embodiment of the present invention.

As illustrated in FIG. 17, a guide 70 provided in the receiving deviceaccording to still another embodiment of the present invention ismovable along a rail 74. The rail 74 may be provided on an inner sidesurface 72 c of the receiving device forming the receiving unit. Therail 74 may extend in a horizontal direction. Side portions 72 a and 72b are provided at both ends of the inner side surface 72 c,respectively. Side fixers 71 a and 71 b having an insertion hole intowhich a part of a side surface of the detecting device is slidablyinserted may be provided in the side portions 72 a and 72 b. A directionin which the insertion hole extends may be perpendicular to a directionin which the rail 74 extends. A bottom fixer 73 configured to support abottom of the detecting device may be provided in the lower part of thereceiving device.

Since the guide 70 is horizontally movable along the rail, in order tofix both sides such that the detecting device is stably accommodated inthe receiving unit, a position of the guide 70 may be moved according toa size of the detecting device.

As an example, in the guide 70, the guide 70 may be moved along the rail74 in order to insert a detecting device having a horizontally extendinglength of w2 that is greater than w1 between the second side fixer 71 band the guide 70 when a distance from the second side fixer 71 b is w1.The guide 70 may move to a point at which a length from the second sidefixer 71 b is w2. Therefore, the detecting device may be insertedbetween the second side fixer 71 b and the guide 70, and the detectingdevice may be fixed not to move by side surfaces of the second sidefixer 71 b and the guide 70.

Meanwhile, the guide 70, which is movable along the rail 74, has aposition that may be fixed by various types of stopper structures. Sincethe stopper structure of the related art can be used, a detaileddescription thereof will be omitted

FIG. 18 is a diagram illustrating a part of a receiving device accordingto still another embodiment of the present invention.

As illustrated in FIG. 18, the receiving device according to stillanother embodiment of the present invention may include a plurality ofguides 80. The plurality of guides 80 are movable along a rail 84 thatextends in a horizontal direction. The rail 84 may be provided on aninner side surface 82 c of the receiving device forming the receivingunit. Side portions 82 a and 82 b are provided at both ends of the innerside surface 82 c, respectively. Side fixers 81 a and 81 b having aninsertion hole into which a part of a side surface of the detectingdevice is slidably inserted may be provided in the side portions 82 aand 82 b. A direction in which the insertion hole extends may beperpendicular to a direction in which the rail 84 extends. A bottomfixer 83 configured to support a bottom of the detecting device may beprovided in the lower part of the receiving device.

According to the user's convenience, a guide adjacent to any of amongthe plurality of guides may be separated at an interval to correspond tothe horizontally extending length of the detecting device and then thedetecting device may be inserted into the guides.

For example, the guide 80 may include a first guide 80 a and a secondguide 80 b. In order to accommodate a detecting device whosehorizontally extending length is w3 in the receiving device, the usermoves the first guide 80 a or the second guide 80 b along the rail 84,and when an interval between the first guide 80 a and the second guide80 b is w3, fixes positions of the first guide 80 a and the second guide80 b and may insert the detecting device therebetween. The detectingdevice may be fixed not to move even when the main body 4 is moved by aside surface of the first guide 80 a and a side surface of the secondguide 80 b.

When positions of the first guide 80 a and the second guide 80 b areappropriately regulated, the detecting device may be inserted intospaces between the first side fixer 81 a and the first guide 80 a,between the first guide 80 a and the second guide 80 b, and between thesecond guide 80 b and the second side fixer 81 b. Therefore, theplurality of detecting devices may be accommodated in one receivingdevice.

The number of guides that are movable along the rail 84 is not limitedto the above. Meanwhile, since the stopper structure of fixing positionsof the first guide 80 a and the second guide 80 b in the related art canbe used, a detailed description thereof will be omitted.

According to the above structure, detecting devices of various sizes maybe stably accommodated in the receiving device having one receivingunit.

While the receiving device provided in the mobile X-ray imagingapparatus has been described above, the structure in which the guide isprovided in the receiving device of the present invention is a structurein which a plate-shaped object of a different size may be stablyaccommodated in one receiving unit. Therefore, the structure may beutilized as a space for receiving a detector for X-ray imaging andutilized in other fields.

According to the embodiment of the present invention, the detector maybe stably supported even when a detector having a smaller size than thereceiving unit is accommodated in the receiving unit by a detectorfixing device provided in the receiving device. Since receiving unitsfor accommodating detectors of different sizes are not separatelyprovided, the receiving device has good space utilization.

What is claimed is:
 1. A receiving device having a receiving unit inwhich a first detecting device is accommodated, the receiving devicecomprising: a fixer provided in the receiving unit and into which a partof a surface of the first detecting device is inserted in order toprevent movement of the first detecting device; and a guide disposed atan inner side surface of the receiving unit and including a detectorsupport having a side that is connected to a rotating shaft to berotatable and configured to support at least one surface of the firstdetecting device and at least one surface of a second detecting devicehaving a different size from the first detecting device.
 2. Thereceiving device according to claim 1, wherein: the guide furtherincludes an elastic member provided between the detector support and theinner side surface of the receiving unit; and the elastic memberprovides an elastic force of pushing the detector support from the innerside surface of the receiving unit.
 3. The receiving device according toclaim 2, wherein, when the first detecting device is inserted into thereceiving unit, the detector support is pressed by the first detectingdevice and rotated to the inner side surface of the receiving unit. 4.The receiving device according to claim 2, wherein the guide furtherincludes a support bracket provided behind the detector support tosupport the elastic member.
 5. The receiving device according to claim1, wherein the guide further includes a side portion mounted at theinner side surface of the receiving unit and having the detector supportrotatably mounted thereon.
 6. The receiving device according to claim 5,wherein: the second detecting device has a smaller size than the firstdetecting device; and when the second detecting device is inserted intothe receiving unit, at least one side surface of the second detectingdevice is supported by the side portion.
 7. The receiving deviceaccording to claim 5, wherein the guide further includes a rotationrestricting portion provided in the form of a groove or a hole in a sidesurface of the detector support to restrict a rotating angle of thedetector support.
 8. The receiving device according to claim 7, whereinthe rotation restricting portion is provided to be a part of aconcentric circle having the same center of rotation as a circle drawnby ends of the detector support.
 9. The receiving device according toclaim 7, wherein the side portion includes an intervention unit that isinsertable into the rotation restricting portion.
 10. The receivingdevice according to claim 1, wherein the fixer includes a bottom fixerprovided in a lower part of the receiving unit and configured to supporta bottom of the first detecting device or a bottom of the seconddetecting device.
 11. The receiving device according to claim 10,wherein, when the first detecting device or the second detecting deviceis mounted in the bottom fixer, the first detecting device or the seconddetecting device is charged.
 12. The receiving device according to claim1, wherein the fixer includes a side fixer having an insertion grooveinto which parts of both side surfaces of the first detecting device areinserted.
 13. The receiving device according to claim 12, wherein theside fixer is provided in the left and right sides of the receivingunit.
 14. The receiving device according to claim 1, wherein a rail isprovided in an inner side surface of the receiving unit, and the guideis movable along the rail.
 15. The receiving device according to claim1, wherein a plurality of the guides are provided.
 16. An X-ray imagingapparatus, comprising: a movable main body; an X-ray generator mountedin the main body and configured to generate X-rays; a detecting deviceconfigured to detect X-rays generated from the X-ray generator; areceiving device mounted in the main body and having a receiving unit inwhich the detecting device is accommodated; and a guide disposed at aninner side surface of the receiving unit and including a detectorsupport configured to support a side surface of the detecting devicehaving a smaller horizontal length than the receiving unit.
 17. TheX-ray imaging apparatus according to claim 16, wherein the detectorsupport is rotatable with respect to a rotation axis.
 18. The X-rayimaging apparatus according to claim 17, wherein the guide includes anelastic member provided between the detector support and an inner sidesurface of the receiving unit.
 19. The X-ray imaging apparatus accordingto claim 18, wherein the elastic member has a directional elastic forcethat increases a distance between the detector support and the innerside surface of the receiving unit.
 20. The X-ray imaging apparatusaccording to claim 17, wherein, when a detecting device having ahorizontal length corresponding to a horizontal length of the receivingunit is inserted into the receiving unit, the detector support ispressed by the detecting device, and a distance between the detectorsupport and an inner side surface of the receiving unit decreases. 21.The X-ray imaging apparatus according to claim 16, wherein: the guidefurther includes a body in which a receiving unit in which the detectorsupport is able to be accommodated is provided; and the detector supportis rotatably mounted in the body.
 22. The X-ray imaging apparatusaccording to claim 16, wherein the receiving unit has left and rightinner sides having a side fixer into which a part of at least one sidesurface of the detecting device is inserted and fixed.
 23. The X-rayimaging apparatus according to claim 16, wherein the receiving unit hasa lower part including a bottom fixer in which a mounting groove inwhich the detecting device is mounted and fixed is formed.
 24. The X-rayimaging apparatus according to claim 23, wherein, when the detectingdevice is mounted in the bottom fixer, the detecting device is charged.25. The X-ray imaging apparatus according to claim 16, wherein thereceiving device includes a rail that horizontally extends, and theguide is movable along the rail.
 26. The X-ray imaging apparatusaccording to claim 25, wherein the rail further includes a stopperconfigured to restrict movement of the guide.
 27. The X-ray imagingapparatus according to claim 16, wherein a plurality of the guides areprovided.
 28. The X-ray imaging apparatus according to claim 27, whereinthe plurality of guides are movable along a rail provided in thereceiving device.